EDA-containing fibronectin increases proliferation of embryonic stem cells.

Embryonic stem cells (ESC) need a set of specific factors to be propagated. They can also grow in conditioned medium (CM) derived from a bovine granulosa cell line BGC (BGC-CM), a medium that not only preserves their main features but also increases ESC´s proliferation rate. The mitogenic properties of this medium were previously reported, ascribing this effect to an alternative spliced generated fibronectin isoform that contains the extra domain A (FN EDA(+)). Here, we investigated if the FN EDA(+) isoform increased proliferation of mouse and human ES cells. We analyzed cell proliferation using conditioned media produced by different mouse embryonic fibroblast (MEF) lines genetically engineered to express FN constitutively including or excluding the EDA domain (FN EDA(-)), and in media supplemented with recombinant peptides containing or not the EDA. We found that the presence of EDA in the medium increased mouse and human ESC's proliferation rate. Here we showed for the first time that this FN isoform enhances ESC's proliferation. These findings suggest a possible conserved behavior for regulation of ES cells proliferation by this FN isoform and could contribute to improve their culturing conditions both for research and cell therapy.

Modulation of chromatin modifying factors' gene expression in embryonic and induced pluripotent stem cells.

Embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs) are a promising source of cells for regenerative medicine because of their potential of self renew and differentiation. Multiple evidences highlight the relationship of chromatin remodeling with stem cell properties, differentiation programs and reprogramming for iPSC obtention. With the purpose of finding chromatin modifying factors relevant to these processes, and based on ChIP on chip studies, we selected several genes that could be modulated by Oct4, Sox2 and Nanog, critical transcription factors in stem cells, and studied their expression profile along the differentiation in mouse and human ESCs, and in mouse iPSCs. In this work, we analyzed the expression of Gcn5l2, GTF3C3, TAF15, ATF7IP, Myst2, HDAC2, HDAC3, HDAC5, HDAC10, SUV39H2, Jarid2, and Bmi-1. We found some genes from different functional groups that were highly modulated, suggesting that they could be relevant both in the undifferentiated state and during differentiation. These findings could contribute to the comprehension of molecular mechanisms involved in pluripotency, early differentiation and reprogramming. We believe that a deeper knowledge of the epigenetic regulation of ESC will allow improving somatic cell reprogramming for iPSC obtention and differentiation protocols optimization.

Induced pluripotent stem cells' self-renewal and pluripotency is maintained by a bovine granulosa cell line-conditioned medium.

Induced pluripotent stem cells (iPSCs) are a promising type of stem cells, comparable to embryonic stem cells (ESCs) in terms of self-renew and pluripotency, generated by reprogramming somatic cells. These cells are an attractive approach to supply patient-specific pluripotent cells, for producing in vitro models of disease, drug discovery, toxicology and potentially treating degenerative disease circumventing immune rejection. In spite of the great advance since iPSCs' establishment, their obtention and propagation is an increasing area of great interest. In a recent work, we have shown that the conditioned medium from a bovine granulosa cell line (BGC-CM) is able to preserve the basic properties of mESCs. Therefore, based on our previous results and the reported resemblance between iPSCs and ESCs, we hypothesized that BGC-CM could provide a favorable context to culturing iPSCs. In this work, we have reprogrammed mouse embryonic fibroblasts obtaining iPSC lines, and showed that they can be propagated in BGC-CM while maintaining self-renewal and pluripotency, evidenced by expression of specific gene markers and capability of in vitro and in vivo differentiation to cell types from the three germ layers. We believe that these findings may provide a novel context to propagate iPSCs to study the molecular mechanisms involved in self-renewal and pluripotency.

Maintenance of murine embryonic stem cells' self-renewal and pluripotency with increase in proliferation rate by a bovine granulosa cell line-conditioned medium.

Murine embryonic stem cells (mESCs) are pluripotent cells that can be propagated in an undifferentiated state in continuous culture on a feeder layer or without feeders in the presence of leukemia inhibitory factor (LIF). Although there has been a great advance since their establishment, ESC culture is still complex and expensive. Therefore, finding culture conditions that maintain the self-renewal of ESCs, preventing their differentiation and promoting their proliferation, is still an area of great interest. In this work, we studied the effects of the conditioned medium from a bovine granulosa cell line (BGC-CM) on the maintenance of self-renewal and pluripotency of mESCs. We found that this medium is able to maintain mESCs' self-renewal while preserving its critical properties without LIF addition. mESCs cultured in BGC-CM expressed the stem cell markers Oct4, Sox2, Nanog, SSEA-1, Klf4, Rex1, and ECAT1. Moreover, mESCs cultured in BGC-CM gave rise to embryoid bodies and teratomas that differentiated effectively to diverse cell populations from endoderm, mesoderm, and ectoderm. Further, we found that mESCs cultured in BGC-CM have an increased proliferation rate compared with cells grown in the mESC standard culture medium supplemented with LIF. These findings may provide a powerful tool to culture mESCs for long periods of time with high proliferation rate while preserving its basic characteristics, contributing to the application of these cells to assess potential tissue engineering and cellular therapy applications.

Diferenciación en cardiomiocitos a partir de células madre embrionarias humanas / Differentiation of Human Embryonic Stem Cells into Cardiomyocytes

Introducción Las células madre son motivo de intensa investigación debido a la posibilidad de su utilización en el tratamiento de numerosas enfermedades, en particular las cardiovasculares. La diferenciación de células madre embrionarias humanas en cardiomiocitos se ha realizado exitosamente in vitro. Se han establecido métodos de cultivo y diferenciación, señales involucradas en la cardiogénesis y los cardiomiocitos generados se han utilizado en modelos de regeneración miocárdica. Sin embargo, aún quedan muchos interrogantes que se están investigando activamente. Objetivo Desarrollar una metodología que permita el cultivo de células embrionarias y su diferenciación en cardiomiocitos. Material y métodos Se utilizaron cuatro líneas de células madre embrionarias humanas. Se cultivaron y diferenciaron a través de los métodos publicados previamente en la bibliografía. El estado indiferenciado y la diferenciación en cardiomiocitos se verificaron por medio de inmunomarcación fluorescente y RT-PCR. Resultados La metodología utilizada permitió cultivar las células y mantenerlas en estado indiferenciado. Aunque con eficacia dispar, se logró la diferenciación en cardiomiocitos de las cuatro líneas celulares utilizadas. La confirmación se realizó por medio de la expresión de factores de transcripción miocárdicos y proteínas estructurales cardíacas. Conclusiones El cultivo y la diferenciación de células madre embrionarias humanas fue posible en nuestro sistema. Estos resultados preliminares nos impulsan a continuar y a desarrollar nuestros métodos con células pluripotentes inducidas.

Background The role of stem cells in the treatment of several conditions, especially heart diseases, is under permanent investigation. Human embryonic stem cells have been successfully differentiated in vitro into cardiomyocytes. Methods of cell culture and cardiomyocyte differentiation are well established; signals regulating cardiogenesis have been identified and the cardiomyocytes generated have been used in models of myocardial regeneration. However, several questions still remain and are currently under active investigation. Objective To develop a culture system that is suitable for the induction of embryonic stem cells to cardiomyocyte differentiation. Material and Methods Four human embryonic stem cell lines were used. The cells were cultured and differentiation was induced using methods previously described. The presence of cells in an undifferentiated state and cardiomyocyte differentiation was detected by immunohistochemical studies (fluorescent staining) and RT-PCR. Results The methodology used allowed stem cells growth in the culture, and maintained them in an undifferentiated state. Cardiomyocyte differentiation was achieved in the four cell lines used, yet with uneven efficacy. This was confirmed by the expression of myocardial transcription factors and heart structural proteins. Conclusions Our system allowed human embryonic stem cell growth and differentiation in the culture. These preliminary results encourage us to continue developing our methods with induced pluripotent stem cells.